Optical combiner lens with lightguide and spacers embedded in lens

ABSTRACT

An optical combiner lens includes a lens, a protective enclosure embedded in the lens, and a lightguide contained in the protective enclosure. First spacers are arranged between a first surface of the lightguide and the protective enclosure to provide a first gap between the lightguide and the lens. Second spacers are arranged between a second surface of the lightguide and the protective enclosure to provide a second gap between the lightguide and the lens. A wearable heads-up display including the optical combiner lens is disclosed.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.62/754,339, filed 1 Nov. 2018, U.S. Provisional Application No.62/782,918, filed 20 Dec. 2018, U.S. Provisional Application No.62/789,909, filed 8 Jan. 2019, U.S. Provisional Application No.62/845,956, filed 10 May 2019, the disclosures of which are incorporatedherein in their entirety by reference.

TECHNICAL FIELD

The disclosure relates to optical combiners and particularly tointegration of optical combiners in lenses and use of such opticalcombiner lenses in wearable heads-up displays.

BACKGROUND

Wearable heads-up displays use optical combiners to combine real worldand virtual images. There are two main classes of optical combiners usedin wearable heads-up displays: free-space combiners and substrate-guidedcombiners. Free-space combiners use one or more reflective, refractive,or diffractive optical elements to redirect light from a light source toa target. In substrate-guided combiners, light enters a guide substrate,e.g., a waveguide or lightguide, typically through an in-couplingelement, propagates along the length of the guide substrate by totalinternal reflection, and exits the guide substrate, typically through anout-coupling element. There may be additional optical elements in theguide substrate to redirect light, e.g., reflect, refract, or diffractlight, within the guide substrate. In wearable heads-up displays havingthe form of glasses, the optical combiners are integrated into at leastone eyeglass, which may or may not be a prescription eyeglass. Despitethe advances in the field of head-mounted displays, it remains achallenge to manufacture a wearable heads-up display that provides asufficient field of view, that can include eyeglasses prescription ifneeded, and that is not too bulky and/or too heavy to be worn on thehead for prolonged periods.

SUMMARY

In a first aspect, an optical combiner lens may be summarized asincluding a lens and a lightguide assembly embedded in the lens. Thelightguide assembly includes a first protective layer, a secondprotective layer, a lightguide having a first lightguide surface and asecond lightguide surface, the lightguide disposed between the firstprotective layer and the second protective layer, a plurality of firstspacers arranged between the first lightguide surface and the firstprotective layer, and a plurality of second spacers arranged between thesecond lightguide surface and the second protective layer.

Variants of the optical combiner lens may include one or more of thefeatures described in A1 to A9 below.

A1: The lens may be molded around the lightguide assembly.

A2: A refractive index of each of the first protective layer and thesecond protective layer may be selected to match a refractive index ofthe lens.

A3: The lens may have a first lens surface that is convex and a secondlens surface that is concave or planar, where the lightguide is arrangedin a stack with the first lens surface and the second lens surface.

A4: Each of the first protective layer and the second protective layermay be made of a transparent polymer.

A5: The lightguide assembly may include an input coupler carried by thelightguide in a position to couple light into the lightguide and anoutput coupler carried by the lightguide in a position to couple lightout of the lightguide.

A6: The first and second protective layers may form a sealed enclosurearound the lightguide and spacers.

A7: The first protective layer may have a patterned surface thatprovides the first spacers and/or the second protective layer may have apatterned surface that provides the second spacers.

A8: The spacers may be microbeads. Alternatively, the spacers may bemicropillars.

A9: The first spacers provide a gap height of at least 2 microns betweenthe first lightguide surface and an opposing surface of the lens and/orthe second spacers provided a gap height of at least 2 microns betweenthe second lightguide surface and an opposing surface of the lens.Alternatively, the first spacers provide a gap height in a range from 2microns to 100 microns between the first lightguide surface and anopposing surface of the lens and/or the second spacers provided a gapheight in a range from 2 microns to 100 microns between the secondlightguide surface and an opposing surface of the lens.

In a second aspect, a wearable heads-up display may be summarized asupport structure, a display light source coupled to the supportstructure, and an optical combiner lens coupled to the supportstructure. The optical combiner lens includes a lens, a protectiveenclosure embedded in the lens, a lightguide contained in the protectiveenclosure, a plurality of first spacers arranged between a first surfaceof the lightguide and the protective enclosure, the first spacersproviding a first gap between the lightguide and the lens, and aplurality of second spacers arranged between a second surface oflightguide and the protective enclosure, the second spacers providing asecond gap between the lightguide and the lens.

Variations of the wearable heads-up display may include one or more ofthe features described in B1 to B8 below.

B1: The protective enclosure may comprise a transparent polymer.

B2: A refractive index of the protective enclosure may be selected tomatch a refractive index of the lens.

B3: A patterned surface of the protective enclosure may provide thefirst spacers and/or the second spacers.

B4: The spacers may be microbeads. Alternatively, the spacers may bemicropillars.

B5: A height of each of the first and second gaps may be at least 2microns. Alternatively, a height of each of the first and second gapsmay be in a range from 2 microns to 100 microns.

B6: The lens has a first lens surface that may be convex and a secondlens surface that may be concave or planar, where the lightguide isdisposed between the first lens surface and the second lens surface.

B7: An output coupler may be carried by the lightguide and positioned tocouple light out of the lightguide.

B8: An input coupler may be carried by the lightguide and positioned tocouple light into the lightguide.

In a third aspect, a wearable heads-up display may be summarized asincluding a support structure, a display light source coupled to thesupport structure, and an optical combiner lens according to the firstaspect (or a variation thereof) coupled to the support structure.

The foregoing general description and the following detailed descriptionare exemplary of the invention and are intended to provide an overviewor framework for understanding the nature of the invention as it isclaimed. The accompanying drawings are included to provide furtherunderstanding of the invention and are incorporated in and constitutepart of this specification. The drawings illustrate various embodimentsof the invention and together with the description serve to explain theprinciples and operation of the invention.

BRIEF DESCRIPTION OF DRAWINGS

In the drawings, identical reference numbers identify similar elementsor acts. The sizes and relative positions of elements in the drawingsare not necessarily drawn to scale. For example, the shapes of variouselements and angles are not necessarily drawn to scale, and some ofthese elements are arbitrarily enlarged and positioned to improvedrawing legibility. Further, the particular shapes of the elements asdrawn are not necessarily intended to convey any information regardingthe actual shape of the particular elements and have been solelyselected for ease of recognition in the drawing.

FIG. 1A is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and microbead spacers in a medium gap between thelens and the lightguide.

FIG. 1B is a cross-sectional view of an optical combiner lens includinga lens, a lightguide without an extension tab, and microbead spacers ina medium gap between the lens and the lightguide.

FIG. 1C is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and microbead spacers in a medium gap between thelens and the lightguide, where a prism input coupler is opticallycoupled to the lightguide.

FIG. 1D is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and spacers in a medium gap between the lens andthe lightguide, where light is coupled into the lightguide through aninput edge of the lightguide.

FIG. 1E is a cross-sectional view of an optical combiner lens includinga meniscus lens, a lightguide, and microbead spacers in a medium gapbetween the meniscus lens and the lightguide.

FIG. 1F is an isometric view of a seal on a top surface of a lightguide.

FIG. 1G is a cross-sectional view of an optical combiner lens includinga planoconvex lens, a lightguide, and spacers in a medium gap betweenthe lens and the lightguide, where the lens and lightguide are heldtogether by a seal that wraps around the lens and the lightguide.

FIG. 1H is a cross-sectional view of an optical combiner lens includinga meniscus lens, a lightguide, and spacers in a medium gap between thelens and the lightguide, where the lens and lightguide are held togetherby a seal that wraps around the lens and the lightguide,

FIG. 1I is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and spacers in a medium gap between the lens andthe lightguide, where the lens and the lightguide are held together by aseal having an inner portion between the lens and lightguide and anouter portion that wraps around the lens and lightguide.

FIG. 1J is a cross-sectional view of a seal that wraps around a sideedge of a lightguide.

FIG. 1K is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and spacers in a medium gap between the lens andthe lightguide, where a side edge of the lightguide is double-beveledand the lens and lightguide are held together by a seal that wrapsaround the lens and the lightguide.

FIG. 1L is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and spacers in a medium gap between the lens andthe lightguide, where a side edge of the lightguide is beveled and thelens and lightguide are held together by a seal that wraps around thelens and the lightguide.

FIG. 1M is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, spacers in a medium gap between the lens and thelightguide, where a side edge of the lightguide is formed into a flangeand the lens and lightguide are held together by a seal that wrapsaround the lens and the lightguide.

FIG. 2A is an isometric view of a lightguide showing input zone, outputzone, and propagation zone of the lightguide, where the input zone islocated on an extension tab of the lightguide.

FIG. 2B is an isometric view of a lightguide showing input zone, outputzone, and propagation zone of the lightguide, where the lightguide doesnot have an extension tab.

FIG. 2C is a top view of a lightguide showing microbeads scatteredacross a top surface of the lightguide.

FIG. 2D is a top view of a lightguide showing microbeads excluded from aselect area of a top surface of the lightguide, where the lightguide hasan extension tab.

FIG. 2E is a top view of a lightguide showing microbeads excluded from aselect area of a top surface of the lightguide, where the lightguidedoes not have an extension tab.

FIG. 2F is a top view of a lightguide showing microbeads with differentconcentrations on select regions of a top surface of the lightguide.

FIG. 3A is a cross-sectional view showing an adhesive layer formed on atop surface of a lightguide.

FIG. 3B is a cross-sectional view showing an adhesive layer with a holeformed on a top surface of a lightguide.

FIG. 3C is a cross-sectional view showing microbeads deposited on theadhesive layer of FIG. 3A.

FIG. 3D is a cross-sectional view showing a lens advancing towards themicrobeads deposited on the adhesive layer of the lightguide of FIG. 3C.

FIG. 3E is a cross-sectional view showing an adhesive layer formed on alens surface and the lens surface advancing towards microbeads depositedon a top surface of a lightguide.

FIG. 3F is a cross-sectional view showing a deformable layer formed on atop surface of a lightguide.

FIG. 3G is a cross-sectional view showing microbeads deposited on thedeformable layer of FIG. 3F.

FIG. 311 is a cross-sectional view showing a lens advancing towards themicrobeads on the deformable layer of FIG. 3G.

FIG. 4A is a cross-sectional view of an optical combiner lens includinga lens, a lightguide, and micropillar spacers in a medium gap betweenthe lens and the lightguide.

FIG. 4B is a cross-sectional view of an optical combiner lens includinga meniscus lens, a lightguide, and micropillars of different heights ina medium gap between the meniscus lens and the lightguide.

FIG. 5A is a cross-sectional view showing a resist layer formed on alightguide.

FIG. 5B is a cross-sectional view showing a mold with a micropillartopological pattern brought into contact with the resist layer on thelightguide of FIG. 5A.

FIG. 5C is a cross-sectional view showing the mold of FIG. 5B pressedinto the resist layer on the lightguide of FIG. 5A.

FIG. 5D is a cross-sectional view showing micropillars formed in theresist layer on the lightguide of FIG. 5A.

FIG. 5E is a cross-sectional view showing micropillars on the lightguideof FIG. 5A without residual material between the micropillars.

FIG. 5F is a cross-sectional view showing a lens advancing towards themicropillars of FIG. 5E.

FIG. 5G is a cross-sectional view showing micropillars between a lensand a lightguide and a seal wrapped around side edges of the lens andthe lightguide.

FIG. 6A is a cross-sectional view of a double lens optical combiner lensincluding a first lens, a lightguide, a second lens, a first set ofmicrobeads in a medium gap between the first lens and the lightguide,and a second set of microbeads in a medium gap between the lightguideand the second lens.

FIG. 6B is a cross-sectional view of a double lens optical combiner lensincluding a meniscus lens, a lightguide, a biconcave lens, a first setof microbeads in a medium gap between the meniscus lens and thelightguide, and a second set of microbeads in a medium gap between thelightguide and the biconcave lens.

FIG. 6C is a cross-sectional view of a double lens optical combiner lensincluding a meniscus lens, a lightguide, a biconcave lens, a first setof micropillars in a medium gap between the meniscus lens and thelightguide, and a second set of micropillars in a medium gap between thelightguide and the biconcave lens.

FIG. 7A is a front elevational view showing a wearable heads-up displayincluding an optical combiner lens.

FIG. 7B is a schematic illustrating light coupled into and out of alightguide of an optical combiner lens.

FIG. 8A is a cross-sectional view of an optical combiner lens includinga lightguide assembly embedded in a lens.

FIG. 8B is a cross-sectional view of a variant of the optical combinerlens of FIG. 8A showing the lightguide and spacers of the lightguideassembly enclosed in a bag and the bag embedded in the lens.

FIG. 8C is a cross-sectional view of a variant of the optical combinerlens of FIG. 8A showing protective layers with patterned surfaces toprovide spacers between the lens and lightguide.

FIG. 9 is a schematic illustrating light coupled into and out of alightguide of an optical combiner lens.

DETAILED DESCRIPTION

In the following description, certain specific details are set forth inorder to provide a thorough understanding of various disclosedimplementations and embodiments. However, one skilled in the relevantart will recognize that implementations and embodiments may be practicedwithout one or more of these specific details, or with other methods,components, materials, etc. In other instances, well-known structuresassociated with portable electronic devices and head-worn devices havenot been shown or described in detail to avoid unnecessarily obscuringdescriptions of the implementations or embodiments. For the sake ofcontinuity, and in the interest of conciseness, same or similarreference characters may be used for same or similar objects in multiplefigures. For the sake of brevity, the term “corresponding to” may beused to describe correspondence between features of different figures.When a feature in a first figure is described as corresponding to afeature in a second figure, the feature in the first figure is deemed tohave the characteristics of the feature in the second figure, and viceversa, unless stated otherwise. For the sake of continuity andconciseness, the same reference numbers may appear in multiple figureswhere they refer to the same features.

In this disclosure, unless the context requires otherwise, throughoutthe specification and claims which follow, the word “comprise” andvariations thereof, such as, “comprises” and “comprising” are to beconstrued in an open, inclusive sense, that is as “including, but notlimited to.”

In this disclosure, reference to “one implementation” or “animplementation” or to “one embodiment” or “an embodiment” means that aparticular feature, structures, or characteristics may be combined inany suitable manner in one or more implementations or one or moreembodiments.

In this disclosure, the singular forms “a,” “an,” and “the” includeplural referents unless the content clearly dictates otherwise. Itshould also be noted that the term “or” is generally employed in itsbroadest sense, that is, as meaning “and/or” unless the content clearlydictates otherwise.

The headings and Abstract of the disclosure provided herein are forconvenience only and do not interpret the scope or meaning of theembodiments.

FIG. 1A shows an optical combiner lens 100 according to one illustrativeimplementation. Optical combiner lens 100 includes a lens 108 and alightguide 112 arranged to form a stack 104. Lens 108 has an outer lenssurface 120, an inner lens surface 124, and lens material 126 betweenlens surfaces 120, 124. Any suitable lens material, such as plastic,e.g., polycarbonate, or glass, may be used as lens material 126. Ingeneral, lens material 126 is transparent to at least some opticalwavelengths of electromagnetic energy, e.g., wavelengths in the visiblerange. In the illustrated example of FIG. 1A, lens 108 is a planoconvexlens, where outer lens surface 120 is a convex surface and inner lenssurface 124 is flat or planar. In other examples, lens 108 may be adifferent type of lens, such as a meniscus lens (see lens 108′ in FIG.1E).

Lightguide 112 is an optical element using total internal reflection totransfer collimated light. For display applications, the collimatedlight may be an image, and lightguide 112 may transfer and replicate theimage to an eye of a user. In the illustrated example, lightguide 112has a top lightguide surface 128, a bottom lightguide surface 132, andlightguide material 134 between top lightguide surface 128 and bottomlightguide surface 132. Lightguide material 134 may be a piece ofmaterial that is capable of transmitting light coupled into thematerial. Preferably, lightguide material 134 is transparent to at leastsome wavelengths of electromagnetic energy, e.g., wavelengths in thevisible range. In some examples, lightguide material 134 may be made oflens material as described above for lens material 126. Lightguidematerial 134 and lens material 126 could be the same material or may bedifferent materials. In one implementation, lightguide 112 is a planarlightguide, where both lightguide surfaces 128, 132 are planar or flat.In other examples not shown, lightguide 112 may be a curved lightguide,where either of lightguide surfaces 128, 132 may be a curved surface,i.e., not lying flat or not in a plane, or a combination of curved andplanar surfaces. In another example not shown, lightguide 112 may be awaveguide comprised of a core between two claddings, where the core hasa higher refractive index compared to the claddings and light propagateswithin the core. The waveguide may be a slab or planar waveguide.

In the stacked arrangement of lens 108 and lightguide 112 shown in FIG.1A, inner lens surface 124 is in opposing relation to top lightguidesurface 128. Outer lens surface 120 is the world side of opticalcombiner lens 100, and bottom lightguide surface 132 is the eye side ofoptical combiner lens 100. A curvature of outer lens surface 120 may beselected to achieve a select eyeglasses prescription and/or to achieveother combiner lens function, such as displaying an image at aparticular distance in front of the combiner lens. One or more coatings,such as anti-scratch coating, anti-reflective coating, and/orIR-blocking coating, may be selectively applied to any of lens surfaces120, 124 and lightguide surfaces 128, 132.

In one implementation, light is coupled into lightguide 112 through aninput coupler 152 that is optically coupled to lightguide 112. Inputcoupler 152 may be attached to lightguide 112, integrally formed withlightguide 112, embedded in top or bottom lightguide surface 128, 132,or otherwise physically coupled to lightguide 112. In the example shownin FIG. 1A, input coupler 152 is physically coupled to an extension tab113 of lightguide 112. Extension tab 113 is a portion of lightguide 112that extends past a periphery of lens 108, which means that inputcoupler 152 is not in a portion of lightguide 112 that is aligned withor in registration with lens 108. FIG. 1B shows an example wherelightguide 112′ does not have an extension tab. In this case, inputcoupler 152 could be in a portion of lightguide 112′ that is alignedwith or in registration with lens 108, as shown.

In one example, input coupler 152 may be any type of optical gratingstructure including, but not limited to, diffraction gratings,holograms, holographic optical elements (e.g., optical elements usingone or more holograms), volume diffraction gratings, volume holograms,surface relief diffraction gratings, and/or surface relief holograms.Input coupler 156 may be of the transmission type, meaning the couplertransmits light and applies designed optical function(s) to the lightduring the transmission, or of the reflection type, meaning the couplerreflects light and applies designed optical function(s) to the lightduring the reflection. For illustration purposes, input coupler 152 isshown as a transmission coupler in FIGS. 1A and 1B. In another example,input coupler 152 may be a non-grating structure. For example, as shownin FIG. 1C, input coupler 152 may be a prism coupler.

In another implementation, light may be coupled into lightguide 112without an input coupler. Referring to FIG. 1D, light may be coupledinto lightguide 112 through an input edge 114 of lightguide 112. Inputedge 114 is a portion of a side edge 117 of lightguide 112, where sideedge 117 of lightguide 112 is a surface of lightguide 112 extendingbetween a perimeter of top lightguide surface 128 and a perimeter ofbottom lightguide surface 132. In the example shown in FIG. 1D, inputedge 114 is located on extension tab 113 of lightguide 112. Iflightguide 112 does not have an extension tab, input edge 114 would beon a portion of lightguide 112 that is aligned with or in registrationwith lens 108. In other words, edge coupling is not limited to anexample where lightguide 112 has an extension tab.

Referring to FIGS. 1A-1D, light is coupled out of lightguide 112 throughan output coupler 156 that is optically coupled to lightguide 112.Output coupler 156 may be attached to lightguide 112, integrally formedwith lightguide 112, embedded in top or bottom lightguide surface 128,132, or otherwise physically coupled to lightguide 112. In one example,output coupler 156 may be any type of optical grating structureincluding, but not limited to, diffraction gratings, holograms,holographic optical elements (e.g., optical elements using one or moreholograms), volume diffraction gratings, volume holograms, surfacerelief diffraction gratings, and/or surface relief holograms. Outputcoupler 156 may be of the transmission type or of the reflection type.For illustration purposes, FIGS. 1A-1D show output coupler 156 as atransmission coupler.

Returning to FIG. 1A, a medium gap 144 is defined within stack 104 andbetween inner lens surface 124 and top lightguide surface 128. Spacers148 are interposed between inner lens surface 124 and top lightguidesurface 128 to maintain medium gap 144 at some height h>0. The height ofmedium gap 144 may be uniform across stack 104 or may vary across stack104, e.g., due to localized sagging of lens 108 or lightguide 112 or dueto inner lens surface 124 and/or top lightguide surface 128 not beingflat or perfectly flat or due to inner lens surface 124 and toplightguide surface 128 not being parallel to each other. To maintainmedium gap 144 at height h>0, some or all of the spacers 148 may contactone or both of inner lens surface 124 and top lightguide surface 128.Spaces 150 around and in between spacers 148, and within medium gap 144,contain a medium, hence the term “medium” used with medium gap 144. Inone example, the medium in spaces 150 may be air or other gaseousmaterial (or inert gas), such as nitrogen. In other examples, the mediummay be a liquid material at room temperatures or a solid material atroom temperatures. In one example, the refractive index n₁ of the mediumin medium gap spaces 150 is substantially different from, e.g., lessthan, the refractive index n₂ of lightguide 112, which allows lightreceived through input coupler 152 (or input edge 114 of lightguide 112)to travel along lightguide 112 to output coupler 156 by total internalreflection.

Evanescent coupling of light between lightguide 112 and lens 108 throughthe medium in spaces 150 may be minimized by an appropriate selection ofthe height of medium gap 144. In general, evanescent coupling dependsexponentially on the height of medium gap 144, decreasing as heightincreases. A threshold height for medium gap 144 can be found abovewhich evanescent coupling between lightguide 112 and lens 108 will beminimal or insignificant. Spacers 148 can be selected to maintain mediumgap 144 at or above the threshold height. In one implementation, thethreshold height for medium gap 144 could be 2 microns. As examples,height h of medium gap 144 may be in a range from 2 to 100 microns, orin a range from 2 to 50 microns, or in a range from 2 microns to 10microns, or in a range from 2 microns to 6 microns, or in a range from 2microns to 4 microns.

In the illustrated examples of FIGS. 1A-1D, each spacer 148 is a roundmicroparticle (“microbead”). Spacers 148 may be made of inorganicmaterial, such as silica or polymer, e.g., poly(methyl metaacrylate)(PMMA). Preferably, the material of spacer 148 is transparent so as toachieve an overall transparency of optical combiner lens 100. Thediameters (or heights) of spacers 148 may be selected to set height h ofmedium gap 144 at or above the threshold height. In one example, eachspacer 148 may have a height (or diameter) in a range from 2 to 100microns, or in a range from 2 microns to 50 microns, or in a range from2 microns to 10 microns, or in a range from 2 microns to 6 microns, orin a range from 2 microns to 4 microns. The refractive index of eachspacer 148 may be n₁ (refractive index of lens 108) or n₂ (refractiveindex of lightguide 112) or may be different from n₁ and n₂. Microbeads148 may be in a monolayer on top lightguide surface 128, or some of themicrobeads 148 may be stacked within medium gap 144. Microbeads 148 maybe scattered across top lightguide surface 128 or may be regionallyconcentrated (in regions with different concentrations) on toplightguide surface 128. Localized clustering of microbeads 148 on toplightguide surface 128 may occur due to attraction forces between themicrobeads. Localized clustering may occur whether microbeads 148 arescattered across top lightguide surface 128 or regionally concentratedon top lightguide surface 128.

When light encounters microbeads (or spacers) 148 on top lightguidesurface 128, there will be scattering of the light by microbeads 148.The concentration of microbeads 148 on top lightguide surface 128 may beselected to minimize perception of the scattered light at lens 108. Ingeneral, the lower the concentration of microbeads 148 on top lightguidesurface 128, the lower the perception of light scattering will be.However, there should be a sufficient number of microbeads 148 tomaintain medium gap 144 within stack 104. In one example, theconcentration of microbeads 148 on top lightguide surface 128, e.g., thenumber of microbeads 148 divided by the area of top lightguide surface128 exposed to medium gap 144, may be in a range from 1 to 100 mm², orin a range from 1 to 50 mm², or in a range from 1 to 15 microbeads permm², or in a range from 5 to 15 microbeads per mm², or in a range from 4to 12 microbeads per mm², where the sizes of the microbeads may be asdescribed above. In general, the microbead concentration can be selectedbased on what would minimize perception of scattered light at lens 108.

In the illustrated examples of FIGS. 1A-1D, lens 108 is a planoconvexlens, lightguide 112 is a planar lightguide, and inner lens surface 124is generally parallel to top lightguide surface 128 so that medium gap144 generally has a uniform height h across the stack. In this case,microbeads 148 with height (or diameter) h will maintain medium gap 144at a generally uniform height h across the stack. There may be localizedvariations in height h of medium gap 144 depending on flatness of innerlens surface 124 and top lightguide surface 128 and/or tolerances inheights of spacers 148. FIG. 1E shows an example where a meniscus lens108′ and lightguide 112 forms a stack 104′. Medium gap 144′ is definedbetween an inner lens surface 124′ of meniscus lens 108′ that is curvedand top lightguide surface 128 that is planar. As a result, medium gap144′ has a variable height vh across stack 104′. As illustrated, ifmicrobeads 148′ of same height are in a monolayer in medium gap 144′,some of microbeads 148 will be wedged between inner lens surface 124′and top lightguide surface 128 while others of the microbeads 148 willcontact only one of top lightguide surface 128 and inner lens surface124′. In this example, medium gap 144′ would still be maintained withinstack 104′ in that microbeads 148, being between inner lens surface 124′and top lightguide surface 128, will act as physical barriers betweeninner lens surface 124′ and top lightguide surface 128.

In the illustrated examples of FIGS. 1A-1E, lens 108 (108′) andlightguide 112 are held together by a seal 160. Seal 160 is interposedbetween lens 108 (108′) and lightguide 112 and engages an adjacentportion of inner lens surface 124 (124′) and an adjacent portion of toplightguide surface 128. In one implementation, seal 160 has a closedloop shape, as illustrated in FIG. 1F, and is located proximate aperiphery 110 of stack 104 (104′). In this position and with this shape,seal 160 circumscribes medium gap 144 (144′) and may provide medium gap144 (144′) with a hermetic seal proximate periphery 110 of stack 104(104′). Seal 160 may be made of one or more non-porous or impermeablematerials to provide medium gap 144 (144′) with the hermetic seal. Insome examples, seal 160 may be made of a curable material, such as a UVcurable resin, or may be a double-sided adhesive pad, or may be othersuitable sealing material or structure.

Other seal structures for holding lens 108 (108′) and lightguide 112together are possible. FIGS. 1G and 1H show a seal 160′ that holds lens108 (108′) and lightguide 112 together by wrapping around a side edge115 (115′) of lens 108 (108′) and a side edge 117 of a portion oflightguide 112 that is aligned with lens 108. Seal 160′ engages the sideedges of lens 108 (108′) and lightguide 112. In the example wherelightguide 112 has extension tab 113, seal 160′ includes a slot 162 toaccommodate extension tab 113. Thus, seal 160′ may engage a portion oftop lightguide surface 128 at the slot 162 as shown in FIGS. 1G and 111.Seal 160′ could be used with a lens 108 that is a planoconvex lens (inFIG. 1G) or a lens 108′ that is a meniscus lens (in FIG. 111). FIG. 1Ishows a seal 160″ that includes an inner portion 164 a interposedbetween lens 108 and lightguide 112, in much the same way as describedfor seal 160 above, and an outer portion 164 b that wraps around lens108 and lightguide 112, in much the same way as described for seal 160′above. Any of seals 160′ and 160″ could also be used with the example ofFIG. 1B where lightguide 112′ does not have an extension tab.

Light propagating inside lightguide 112 that is not coupled into outputcoupler 152 may emerge at side edge 117 of lightguide 112 as straylight. To manage the stray light, a seal engaging side edge 117 oflightguide 112 may double up as a light dump for lightguide 112. Forexample, FIG. 1J shows seal 160′ (previously shown in FIGS. 1G and 111)wrapped around a side edge 117 of a portion of lightguide 112 that wouldbe in registration with lens 108 (see FIGS. 1G and 111). Light fromlightguide 112 reaching a portion of side edge 117 where seal 160′ islocated will be dumped into seal 160′, where seal 160′ could absorband/or scatter the dumped light. In one example, nanoparticles, e.g.,silver nanoparticles and the like, may be incorporated into seal 160′ toassist seal 160′ with absorbing and/or scattering the light dumped bylightguide 112. In general, a seal engaging any portion of side edge 117of lightguide 112 (e.g., seal 160′ in FIGS. 1G and 1I-1 or seal 160″ inFIG. 1I) may function as a light dump for lightguide 112 and mayincorporate nanoparticles as described above. Although not shown in thedrawings, any seal engaging side edge 117′ of lightguide 112′ (in FIG.1B) may also function as a light dump as described above.

In one implementation, side edge 117 may be shaped to facilitatecoupling of stray light from lightguide 112 into an adjacent seal. FIGS.1K and 1L show examples where side edge 117, or a portion thereof, isbeveled or includes angled surface(s). In the illustrated examples, thebevel edge treatment is applied to a portion of side edge 117 on aportion of lightguide 112 that is aligned with lens 108. In otherexamples, the bevel edge treatment may be extended to the portion ofside edge 117 on extension tab 113 of lightguide 112. FIG. 1M shows anexample where side edge 117 is formed into a flange. In FIGS. 1K, 1L,and 1M, seal 160′″ adjacent to side edge 117 may be suitably shaped toconform to the shape of side edge 117 and may have properties tofunction as a light dump as previously described. Other edge shapes forside edge 117 are possible, such as convex shape, bullnose shape,chamfer shape, and the like. Other edge treatments that includemodifying a surface of side edge 117, such as applying a coating to sideedge 117, polishing side edge 117, etching side edge 117, or rougheningside edge 117, may be used in lieu of or in addition to edge shapingtreatment.

FIG. 2A illustrates lightguide 112 with an input zone 176, an outputzone 180, and a propagation zone 184. Input zone 176 is where lightguide112 receives light. Input zone 176 may be a portion of lightguide 112that is aligned with or in registration with input coupler 152 (in FIG.1A). If light is coupled into lightguide 112 through input edge 114,then input zone 176 will coincide with input edge 114. Output zone 180is where light exits lightguide 112. Output zone 180 is a portion oflightguide 112 that is aligned with or in registration with outputcoupler 156 (in FIG. 1A). Propagation zone 184 is a portion oflightguide 112 between input zone 176 and output zone 180. Propagationzone 184 provides a propagation path for light from input zone 176 tooutput zone 180. In the example shown in FIG. 2A, input zone 176 islocated in extension tab 113 of lightguide 112. FIG. 2B shows an examplelocation of input zone 176 for lightguide 112′ that does not have anextension tab.

FIGS. 2C-2F show various examples of positioning or distributingmicrobeads 148 on top lightguide surface 128 of lightguide 112. Toplightguide surface 128 may have a seal area 128 a generally proximate aperiphery of lightguide 112 to make contact with a seal (see seal 160 inFIGS. 1A-1D and seal portion 164 a in FIG. 1I). In general, microbeads148 will be excluded from seal area 128 a. Top lightguide surface 128has a medium gap area 128 b that is exposed to medium gap 144 (in FIGS.1A-1D and 1G-1I) or medium gap 144′ (in FIG. 1E). Typically, seal area128 a if present will be in a closed loop form circumscribing medium gaparea 128 b. In FIG. 2C, microbeads 148 are scattered across medium gaparea 128 b—this generally means that there are no defined regionalconcentrations of microbeads 148 on top lightguide 128. In FIGS. 2D, 2E,2F, microbeads 148 are regionally concentrated across medium gap 128b—this means that different areas with distinct concentrations ofmicrobeads 148 can be identified.

In FIGS. 2D, 2E, and 2F, medium gap area 128 b of top lightguide surface128 has a first regional area 128 ba with a first microbeadconcentration and a second regional area 128 bb with a second microbeadconcentration, where the first microbead concentration is lower than thesecond microbead concentration. In FIGS. 2D and 2E, the first microbeadconcentration is zero. In FIG. 2F, the first microbead concentration isnot zero but is lower than the second microbead concentration. In theillustrated examples of FIGS. 2D and 2F (corresponding to a case wherethe input zone 176 is on extension tab 113 of lightguide 112), firstregional area 128 ba with first microbead concentration overlaps outputzone 180 (in FIG. 2A) and propagation zone 184 (in FIG. 2A). In theillustrated example of FIG. 2E (corresponding to a case where the inputzone is not on an extension tab of lightguide 112), first regional area128 ba overlaps input zone 176 (in FIG. 2B), output zone 180 (in FIG.2B), and propagation zone 184 (in FIG. 2B). In general, first regionalarea 128 bb may overlap any or all of input zone 176, output zone 180,and propagation zone 184. In general, second regional area 128 bb withsecond microbead concentration will be an area outside of first regionalarea 128 ba with first microbead concentration. The low to noconcentration of microbeads 148 in first regional area 128 ba may beused to minimize any detrimental effects of microbeads 148 on lightguideperformance as light travels from input zone 176 to output zone 180through propagation zone 184.

To achieve selective positioning of microbeads 148 on top lightguidesurface 128 (as shown in FIGS. 2D, 2E, and 2F), the area(s) of toplightguide surface 128 from which microbeads 148 are to be excluded orapplied in a low concentration may be masked before applying themicrobeads 148 to the top lightguide surface 128. Any microbeads 148falling on the mask may be removed with the mask afterwards.Alternatively, microbeads 148 may be scattered across the entire toplightguide surface 128, followed by selective removal of the microbeads148 from the areas of top lightguide surface 128 where microbeads 148are to be excluded or reduced to a lower concentration.

One method of disposing microbeads in medium gap 144 (in FIGS. 1A-1D,1G, and 1I) may include mixing microbeads into a liquid carrier, e.g.,deionized water or alcohol or gel, agitating the mixture of microbeadsand liquid carrier, e.g., by ultrasonic vibration and the like, suchthat the microbeads are uniformly distributed throughout the mixture,coating the top lightguide surface 128 (or the inner lens surface 124)with the mixture, and allowing the liquid carrier to evaporate, wherethe microbeads remain on the top lightguide surface 128 (or the innerlens surface 124) after the evaporation of the liquid carrier. Coatingmay be by clip coating, spin coating, spray coating, and the like. Themicrobeads are expected to cling to the coated lightguide surface 128(or inner lens surface 124) by electrostatic force. The method furtherincludes bringing lens 108 and lightguide 112 together to trap themicrobeads between inner lens surface 124 and top lightguide surface128. A slight pressure may be applied to the lens 108 and/or lightguide112 to slightly compress the microbeads between the surfaces 124, 128.If seal 160 is to be formed between lens 108 and lightguide 112, sealantmaterial may be applied to either of surfaces 124, 128 prior to bringingthe lens 108 and lightguide 112 together. Alternatively, sealantmaterial may be injected between lens 108 and lightguide 112 and/orapplied around the side edges of lens 108 and lightguide 112 after themicrobeads are trapped between inner lens surface 124 and top lightguidesurface 128.

If microbeads 148 are to be excluded from certain areas of toplightguide surface 128 (or applied in a lower concentration compared toother areas of top lightguide surface 128), a mask may be applied to toplightguide surface 128 prior to coating top lightguide surface 128 withthe mixture of microbeads and liquid carrier. After coating toplightguide surface 128 with the mixture and prior to bringing the lens108 and lightguide 112 together to trap the microbeads between innerlens surface 124 and top lightguide surface 128, the mask may be removedalong with any microbeads that may have fallen on the mask.Alternatively, after coating top lightguide surface 128 with themixture, microbeads may be removed from select areas of top lightguidesurface 128 prior to bringing lens 108 and lightguide 112 together totrap the microbeads between inner lens surface 124 and top lightguidesurface 128. If the mixture is applied to inner lens surface 124instead, the mask may be used on the inner lens surface 124 to form thedesired microbead distribution pattern on inner lens surface 124, ormicrobeads may be selectively removed from inner lens surface 124 toform the desired microbead distribution pattern on inner lens surface124. When lens 108 and lightguide 112 are brought together, themicrobead distribution pattern on inner lens surface 124 will betransferred to top lightguide surface 128.

Any of the methods described above for disposing microbeads in mediumgap 144 may be equally applied to disposing microbeads in medium gap144′ (in FIGS. 1E and 111).

To prevent microbeads 148 from rolling around inside medium gap 144,e.g., if electrostatic force is not sufficient to keep the microbeads148 in place, microbeads 148 may be physically retained on at least oneof inner lens surface 124 and top lightguide surface 128. In oneexample, microbeads 148 may be retained in place by an adhesive layer ontop lightguide surface 128 or inner lens surface 124. Referring to FIG.3A, an adhesive material is applied to top lightguide surface 128 toform an adhesive layer 192 on top lightguide surface 128. The adhesivematerial may be, for example, a curable resin. The adhesive material maybe applied by dip coating, spin coating, spray coating, brushing, or thelike. If microbeads are to be excluded from some areas of top lightguidesurface 128, the adhesive material may be applied only to areas of toplightguide surface 128 where microbeads will be positioned, i.e., theadhesive layer may have holes corresponding to portions of toplightguide surface 128 where microbeads are to be excluded (as anexample, see hole 196 in adhesive layer 192 in FIG. 3B). A mixture ofliquid carrier and microbeads is prepared as described above. Themixture of microbeads and liquid carrier is then applied on top of theadhesive layer 192, followed by allowing the liquid carrier toevaporate. FIG. 3C shows microbeads 148 on adhesive layer 192. Theadhesive material in adhesive layer 192 will secure the microbeads 148to top lightguide surface 128. If the adhesive material is a curableresin, the adhesive layer is exposed to ultraviolet light (or othersuitable heat source based on the nature of the curable resin) forcuring. Preferably, adhesive layer 192 is optically transparent, i.e.,transparent to at least some wavelengths of electromagnetic energy,e.g., wavelengths corresponding to visible light. In one example,adhesive layer 192 may be index matched to lightguide 112 or have anindex of refraction that is less than that of lightguide 112. As shownin FIG. 3D, seal 160 may be applied to top lightguide surface 128, e.g.,outside of the portion of top lightguide surface 128 carrying microbeads148. Then, lens 108 can be brought into contact with microbeads 148 andseal 160 to trap microbeads 148 between inner lens surface 124 and toplightguide surface 128.

In another example, as shown in FIG. 3E, adhesive layer 192 is appliedon inner lens surface 124 in the same manner described above, andmicrobeads 148 are deposited on top lightguide surface 128 in the samemanner described above. The lens 108 with adhesive layer 192 is broughtinto contact with microbeads 148 on top lightguide surface 128 to trapmicrobeads 148 between inner lens surface 124 and top lightguide surface128. As in the previous example, microbeads 148 will be held in place byadhesive layer 192 on lens 108. As in the previous example, adhesivelayer 192 is preferably optically transparent at least in the visiblewavelength range. For the example of FIG. 3E, the refractive index ofadhesive layer 192 does not need to be index matched to either oflightguide 112 and lens 108. If microbeads 148 are to be excluded froman area (or areas) of top lightguide surface 128, the desired microbeaddistribution pattern can be established using any of the previouslydescribed methods before bringing lens 108 with adhesive layer 192 intocontact with microbeads 148 on top lightguide surface 128.

In another example, microbeads 148 may be retained in place by adeformable material applied to top lightguide surface 128 or inner lenssurface 124. Referring to FIG. 3F, a deformable material is applied totop lightguide surface 128 to form a deformable layer 194 on toplightguide surface 128. The deformable material may be, for example, asoft polymer that is transparent to wavelengths in the visible range.The deformable material may adhere to the top lightguide surface 128 byan optically transparent adhesive or may cling to top lightguide surface128 by electrostatic force. In one example, deformable layer 194 may beindex matched to lightguide 112 or have an index of refraction that isless than that of lightguide 112. A mixture of microbeads and liquidcarrier is prepared as described above. The mixture of liquid carrierand microbeads is then applied on top of deformable layer 194, followedby allowing the liquid carrier to evaporate. If microbeads are to beexcluded from certain areas of top lightguide surface 128, thedeformable layer 194 may double up as a mask. For example, there may bea portion of deformable layer 194 that is separable from the bulk ofdeformable layer 194 after applying the mixture on top of deformablelayer 194. Alternatively, a mask may be applied on top of deformablelayer 194 prior to applying the mixture on top of the deformable layer194. Alternatively, the microbeads could be selectively removed from thedeformable layer 194 to achieve the desired microbead distributionpattern on top lightguide surface 128. FIG. 3G shows microbeads 148 ondeformable layer 194. In one example, seal 160 may be applied on toplightguide surface 128, e.g., outside of the portion of top lightguidesurface 128 carrying deformable layer 194 and microbeads 148. When lens108 and lightguide 112 are brought together to trap the microbeadsbetween the inner lens 124 and top lightguide surface 124, as shown inFIG. 311, a slight pressure is applied to lens 108 and/or lightguide112, which will slightly press the microbeads 148 into deformable layer194. The deformable layer 194 will deform around the microbeads 148 andthereby hold the microbeads 148 in place.

Any of the methods described above for retaining microbeads 148 in placein medium gap 144 (in FIGS. 1A-1D, 1G, and 1I) may be equally applied toretaining microbeads 148 in place in medium gap 144′ (in FIGS. 1E and111).

FIG. 4A shows an optical combiner lens 200 including lens 208 andlightguide 212 arranged in a stack 204. Medium gap 244 is defined withinstack 204 and between inner lens surface 224 and top lightguide surface228. Spacers 248 are disposed between inner lens surface 224 and toplightguide surface 228 to maintain medium gap 244. In FIG. 4A, spacers248 are micropillars. Lens 208 has the same properties as describedabove for lens 108, and lightguide 212 has the same properties asdescribed above for lightguide 112. Input coupler 252 may be positionedto couple light into lightguide 212 as described for input coupler 152and lightguide 112. Output coupler 256 may be positioned to couple lightout of lightguide 212 as described above for output coupler 156 andlightguide 112. Lens 208 and lightguide 212 may be held together by seal260 (or other seal structures previously described), as described forlightguide 112 and seal 160 (or other seal structures). Optical combinerlens 200 thus differs from optical combiner lens 100 described above(FIGS. 1A-1D, 1G, and 1I) in that spacers 248 are micropillars insteadof microbeads.

Spaces 250 between micropillars 248 contain a medium as described abovefor space 150 between microbeads 148 (in FIGS. 1A-1D, 1G, and 1I). Inone implementation, each micropillar 248 may extend between and contactboth of inner lens surface 224 and top lightguide surface 228. Inanother implementation, at least some of the micropillars 248 may extendbetween and contact both of inner lens surface 224 and top lightguidesurface 228. Micropillars 248 may be made of the same material asdescribed above for spacers 148. Micropillars 248 may be selected tomaintain medium gap 244 at or above the threshold height to minimizeevanescent coupling, as described above for spacers 148. Micropillars248 may have the same example height ranges described above for spacers148. For example, each micropillar 248 may have a height in a range from2 to 100 microns, or in a range from 2 microns to 50 microns, or in arange from 2 microns to 10 microns, or in a range from 2 microns to 6microns, or in a range from 2 microns to 4 microns. In some examples, anaspect ratio (width to height ratio) of each micropillar 248 may be in arange from 0.5 to 1.5. In general, the width of each micropillar 248need only be sufficient to provide a suitable mechanical support ofmedium gap 144.

The refractive index of each micropillar spacer 248 may be n₁(refractive index of lens 208) or n₂ (refractive index of lightguide212) or may be different from n₁ and n₂, as described above for spacer148. The concentration of micropillars 248 on top lightguide surface 228may be selected to minimize perception of light scattering at lens 208.In general, the lower the concentration of micropillars 248, the lowerthe perception of light scattering will be. In one example, theconcentration of micropillars spacers 248 on top lightguide surface 228,i.e., the number of micropillars 248 divided by the surface area of toplightguide surface exposed to medium gap 244, may be in a range from 1to 50 micropillars per mm², or in a range from 1 to 25 per mm², or in arange from 1 to 8 micropillars per mm², or in a range from 1 to 6micropillars per mm², or in a range from 1 to 4 micropillars per mm².However, this concentration can generally be selected based on whatwould minimize perception of light scattering at lens 208. Micropillars248 may be selectively excluded from areas of the top lightguide surface228 as described above for the microbeads or applied in regionalconcentrations on top lightguide surface 228 as described above for themicrobeads.

In the example shown in FIG. 4A, lens 208 is a planoconvex lens,lightguide 212 is a planar lightguide, and inner lens surface 224 isgenerally parallel to the top lightguide surface 228 so that medium gap244 generally has a uniform height h across the stack. In this case,micropillars 248 with height h will maintain medium gap 244 at height hacross stack 204. In FIG. 4B, lens 208′ is a meniscus lens, andmicropillars 248′ are disposed in medium gap 244′ between inner lenssurface 224′ that is curved and top lightguide surface 228 that isplanar. Medium gap 244′ has a variable height vh across stack 204′ dueto inner lens surface 224′ being curved and/or not being parallel to toplightguide surface 228. In the illustrated example of FIG. 4B,micropillars 248′ have different heights to accommodate the variation inheight of medium gap 244′. Each micropillar 248′ may extend between andcontact both inner lens surface 224′ and top lightguide surface 228.Further, the surfaces of micropillars 248′ in contact with inner lenssurface 224′ may be curved to conform with inner lens surface 224′. Thevariable height vh of medium gap 244′ may be within the described rangesfor the height h of medium gap 244 in FIG. 4A. Spaces 250′ between andaround micropillars 248′ may contain a medium, such as described abovefor spaces 250 or spaces 150.

One method of disposing micropillars 248 in medium gap 244 may includeforming micropillars 248 on top lightguide surface 228 by, for example,nanoimprint lithography. In one example, this may include making a moldwith the micropillar topological pattern, i.e., a desired arrangement ofthe micropillars in the medium gap. In FIG. 5A, a resist layer 292,e.g., a polymer, is formed on top lightguide surface 228. The resistlayer may be formed by a suitable coating process, such as spin coatingand the like. In FIG. 5B, a mold 194 with the micropillar topologicalpattern is brought into contact with resist layer 292 and pressedagainst resist layer 292. The assembly (mold, resist layer, andlightguide) is heated to a temperature above a glass-transitiontemperature of resist layer 292, which would allow mold 194 to deformresist layer 292 and transfer the micropillar pattern to resist layer292, as shown in FIG. 5C. The deformed resist layer 292 is cooled tobelow its glass transition temperature, and mold 194 is removed from thedeformed resist layer. Micropillars 248 are now formed on lightguide212, as shown in FIG. 5D. There will be residual material 192 a inbetween the micropillars. Residual material 192 a may be left betweenmicropillars 248, as shown in FIG. 5D, or may be removed from betweenmicropillars 248, e.g., by etching, as shown in FIG. 5E. Seal 260 may beformed in resist layer 292 at the same time that micropillars 248 areformed in resist layer 292, as shown in FIGS. 5B to 5E. After separatingmold 194 from resist layer 292, seal 260 may be heated to a temperatureabove a glass transition temperature of the seal material/resist layermaterial, followed by bringing lens 208 in contact with seal 260 andmicropillars 248, as shown in FIG. 5F. This will result in seal pad 260engaging lens 208 and lightguide 212, with the micropillars 248 trappedbetween inner lens surface 224 and top lightguide surface 228.Alternatively, or in addition to seal 260, a seal that wraps around lens208 and the portion of lightguide 212 in registration with lens 208 maybe formed. For example, after bringing lens 208 in contact withmicropillars 248 on lightguide 212, as shown in FIG. 5G, seal 260′ maybe applied along the edge surfaces of lens 208 and the portion oflightguide 212 in registration with lens 208.

The method described above may be used to dispose micropillars 248′ (inFIG. 4B) in medium gap 244′ (in FIG. 4B) with a mold having a suitablemicropillar topological pattern.

FIG. 6A shows a double lens optical combiner lens 300 including firstlens 308 a, lightguide 312, and second lens 308 b arranged in a stack304, with lightguide 312 disposed between first lens 308 a and secondlens 308 b. Medium gap 344 a is defined within stack 304 and betweeninner lens surface 324 a and top lightguide surface 328. Medium gap 344b is defined within stack 304 and between inner lens surface 324 b andtop lightguide 328. Spacers 348 a are disposed between inner lenssurface 324 a and top lightguide surface 328 to maintain medium gap 344a. Spacers 348 b are disposed between inner lens surface 324 b andbottom lightguide surface 332 to maintain medium gap 344 b. Lens 308 ahas the same properties as described above for lens 108, and lightguide312 has the same properties as described above for lightguide 112. Inthe illustrated example of FIG. 6A, first lens 308 a is a planoconvexlens, where inner lens surface 324 a is planar and outer lens surface320 a is convex. Second lens 308 b is a planoconcave lens, where innerlens surface 324 b is planar and outer lens surface 320 a is concave.Input coupler 352 may be positioned to couple light into lightguide 312as described for input coupler 152 and lightguide 112. Output coupler256 may be positioned to couple light out of lightguide 312 as describedabove for output coupler 156 and lightguide 112. Lens 308 a, lightguide312, and lens 308 b may be held together by seals 360 a, 360 b. Opticalcombiner lens 300 thus differs from optical combiner lens 100 describedabove (FIGS. 1A-1D, 1G, and 1I) in that optical combiner lens 300 hastwo lenses 308 a, 308 b, two medium gaps 344 a, 344 b, and spacers 348a, 348 b disposed in the two medium gaps 344 a, 344 b. Outer lenssurface 320 a of first lens 308 a may be the world side of opticalcombiner lens 300, and outer lens surface 320 b of second lens 308 b maybe the eye side of optical combiner lens 300. Curvatures of lenssurfaces 320 a, 3206 may be selected to achieve a desired eyeglassesprescription.

Inner lens surface 324 a of second lens 308 a is in opposing relation totop lightguide surface 328, and medium gap 344 a of height h_(a) isformed between inner lens surface 324 a and top lightguide surface 328.Medium gap 344 a is maintained by spacers 348 a arranged between innerlens surface 324 a and top lightguide surface 328. Similarly, inner lenssurface 324 b of second lens 308 b is in opposing relation to bottomlightguide surface 332, and medium gap 344 b of height h_(b) is formedbetween inner lens surface 324 b and bottom lightguide surface 332.Medium gap 344 b is maintained by spacers 348 b arranged between innerlens surface 324 b and bottom lightguide surface 332. In the illustratedexample of FIG. 6A, spacers 348 a, 348 b are microbeads. Spaces 350 abetween microbeads 348 a contain a medium, and spaces 350 b betweenmicrobeads 348 b containing a medium, as described above for space 150between microbeads 148 (in FIGS. 1A-1D, 1G, and 1I). Medium gaps 344 a,344 b may be hermetically sealed, e.g., by seal 360 a, 360 b or anyother sealing structure that circumscribes medium gaps 344 a, 344 b.Microbeads 348 a, 348 b may be made of the same material as describedabove for microbeads 148. Microbeads 348 a may be selected to maintainmedium gap 344 a at or above the threshold height to minimize evanescentcoupling between lightguide 312 and first lens 308 a, as previouslydescribed. Microbeads 348 b may be selected to maintain medium gap 344 bat or above the threshold height to minimize evanescent coupling betweenlightguide 312 and second lens 308 b, as previously described. As anexample, each microbead 348 a, 348 b may have a height in a range from 2to 100 microns, or in a range from 2 microns to 50 microns, or in arange from 2 microns to 10 microns, or in a range from 2 microns to 6microns, or in a range from 2 microns to 4 microns.

Spacers 348 a, 348 b maintain medium gaps 344 a, 344 b, respectively, ata nonzero height h_(a), h_(b), respectively. In general, spacers 344 a,344 b may satisfy the same requirements as described above for spacers148, with reference to FIGS. 1A-1D, 1G, and 1I, in terms of material,height (or diameter), refractive index, and concentration (theconcentration of spacers 344 a will be relative to top lightguidesurface 348 a, while the concentration of spacers 344 b will be relativeto bottom lightguide surface 332). Any of the methods described abovefor retaining spacers 148 on inner lens surface 124 and/or toplightguide surface 128 may be used to retain spacers 348 a on inner lenssurface 324 a and/or top lightguide surface 328 and spacers 348 b oninner lens surface 324 b and/or bottom lightguide surface 332. Further,spacers 348 a may be scattered across respective top lightguide surface328 or regionally concentrated on respective lightguide surface 328, aspreviously described with reference to FIGS. 2C-2F. Similarly, spacers348 b may be scattered across bottom lightguide surface 332 orregionally concentrated on bottom lightguide surface 332, in the samemanner described for spacers 148 and top lightguide surface 128 in FIGS.2C-2F. For the double lens optical combiner lens 300, light enterslightguide 312 through input coupler 352 (or input edge of lightguide312 if edge coupling is used), travels along lightguide 312 by totalinternal reflection, and exits lightguide 312 through output coupler356. Lens 308 b receives the light coming out of output coupler 356.

In FIG. 6A, first lens 308 a is a planoconvex lens, second lens 308 b isa planoconcave lens, and lightguide 312 is a planar lightguide, whichresults in medium gaps 344 a, 344 b with generally uniform heightsh_(a), h_(b), respectively. In FIG. 6B, first lens 308 a′ is a meniscuslens, second lens 308 b′ is a biconcave lens, and lightguide 212 is aplanar lightguide, which results in medium gaps 344 a′, 344 b′ withvariable height vh_(a), vh_(b), respectively. Medium gap 344 a′ isformed between inner lens surface 324 a′ of first lens 308 a and toplightguide surface 328, and medium gap 344 b′ is formed between innerlens surface 324 b′ of second lens 308 b′ and bottom lightguide surface332. Spacers 348 a′ maintain medium gap 344 a′, and spacers 348 b′maintain medium gap 344 b′. Spacers 348 a′, 348 b′ are shown asmicrobeads in FIG. 6B and may have the same characteristics describedabove for spacers 348 a, 348 b, respectively. Some of the microbeadspacers 348 a′ are wedged between inner lens surface 324 a′ and toplightguide surface 328, while others of the microbead spacers 348 a′ maycontact, or may be retained on, only one of the top lightguide surface328 and inner lens surface 324 a. Similarly, some of the microbeadspacers 348 b′ are wedged between inner lens surface 324 b′ and bottomlightguide surface 332, while others of the microbead spacers 348 b′ maycontact, or may be retained on, only one of the bottom lightguidesurface 332 and inner lens surface 324 b′.

In optical combiner lens 300″ of FIG. 6C, spacers 348 a″ maintain mediumgap 344 a″ and spacers 348 b″ maintain medium gap 344 b″. Opticalcombiner lens 300″ of FIG. 6C thus differs from optical combiner lens300′ of FIG. 6B in that spacers 348 a″, 348 b″ are micropillars. In FIG.6C, micropillar spacers 348 a″ have different heights to maintain mediumgap 344 a″ of height vh_(a), and each micropillar 348 a″ may extendbetween, and contact both of, inner lens surface 324 a′ and toplightguide surface 328. Similarly, micropillar spacers 348 b″ havedifferent heights to maintain medium gap 344 b″ of height vh_(b), andeach micropillar 348 b″ may extend between, and contact both of, innerlens surface 324 b′ and bottom lightguide surface 332. Spacers 348 a″,348 b″ may have the same properties described above for spacers 248 interms of material, height ranges, refractive indices, and concentrationrelative to respective surfaces of lightguide 312. The heights ofspacers 348 a″, 348 b″ can be suitably selected to maintain medium gaps344 a″, 344 b″, respectively. Spaces 350 a″ around and in betweenspacers 348 a″ and spaces 350 b″ around and in between spacers 348 b″may contain a medium, such as air and the like, as described for all theother spaces in medium gaps. Medium gaps 344 a″, 344 b″ may behermetically sealed at a periphery of stack 304″ by seals 360 a, 360 bdisposed between lenses 308 a′, 308 b′ and lightguide 312 or other sealstructures that hold lenses 308 a′, 308 b′ and lightguide 312 together.Although not shown, a seal structure that wraps around the side edge oflightguide 312 may act as a light dump as previously explained withreference to FIGS. 1G, 111, and 1I.

Any of the optical combiner lenses described above may be integratedinto a wearable heads-up display. For illustration purposes, FIG. 7Ashows optical combiner lens 100 carried by a support structure 400 of awearable heads-up display 404. Support structure 400 is in the form ofan eyeglasses frame including a front frame 408 and temples 412 a, 412 battached to opposite sides of front frame 408. In one example, opticalcombiner lens 100 is fitted into a lens mount 416 in front frame 408. Asecond eyeglasses lens 420 is fitted into a lens mount 424 in frontframe 408. Lens 420 may or may not be an optical combiner lens.

Referring to FIG. 7B, wearable heads-up display 404 includes a displaylight source 428, such as a projector, a scanning laser projector, amicrodisplay, or the like, which may be carried in temple 412 a (in FIG.7A). Light from display light source 428 enters lightguide 112 throughinput coupler 152, travels along lightguide 112 by total internalreflection, and exits lightguide 112 through output coupler 156. Thelight exiting output coupler 156 enters the pupil of an eye 432 of auser wearing the wearable heads-up display. Although FIG. 7B showsoptical combiner lens 100 coupling light from display light source 428to eye 432, it should be understood that any of the optical combinerlenses described above, including single lens and double lens opticalcombiner lenses, may be used to couple light from display light source428 to eye 432.

FIG. 8A shows another optical combiner lens 500 that may be used in awearable heads-up display. Optical combiner lens 500 includes alightguide assembly 502 and a lens 504. Lightguide assembly 502 isembedded in lens 504. For example, lightguide assembly 502 may beembedded in lens 504 by molding or casting lens 504 around lightguideassembly 502. Lightguide assembly 502 includes a lightguide 512 having atop lightguide surface 528 and a bottom lightguide surface 532—the terms“top” and “bottom” are relative to the orientation of the drawing.Spacers 548 a are positioned on, or in contact with, top lightguidesurface 528. A protective layer 549 a is applied on the layer formed byspacers 548 a. Spacers 548 a define a first medium gap 544 a that isdisposed between top lightguide surface 528 and lens 504, or between toplightguide surface 528 and protective layer 549 a. Spacers 548 b arepositioned underneath, or in contact with, bottom lightguide surface532. A protective layer 549 b is applied underneath the layer formed bythe spacers 548 b. Spacers 548 b define a second medium gap 544 b thatis disposed between bottom lightguide surface 532 and lens 504, orbetween bottom lightguide surface 532 and protective layer 549 b.Protective layers 549 a, 549 b form a protective enclosure aroundlightguide 512 and spacers 548 a, 548 b. In one implementation,protective layers 549 a, 549 b are thin films of material that aredeformable or conformable, which would allow protective layers 549 a,549 b to conform to the general shape formed by the lightguide 512 andspacers 548 a, 548 b. For example, protective layers 549 a, 549 b may bemade of a soft polymer. Protective layers 549 a, 549 b are preferablymade of a material that is transparent to at least wavelengths in thevisible range. Thus, for example, protective layers 549 a, 549 b may bemade of a soft polymer that is transparent to wavelengths in the visiblerange.

The end portions of protective layers 549 a, 549 b that extend beyond aperiphery of lightguide 512 may be joined or otherwise sealed togetherto form a hermetic enclosure around lightguide 512, spacers 548 a, 548b, and medium gaps 544 a, 544 b. Alternatively, the end portion ofprotective layer 549 a may be sealed against lightguide surface 528 neara periphery of lightguide 512 to form a hermetic seal around medium gap544 a, and the end portion of protective layer 549 b may be sealedagainst lightguide surface 532 near a periphery of lightguide 512 toform a hermetic seal around medium gap 544 b. Alternatively, as shown inFIG. 8B, portions of a protective bag 549 that slips over lightguide 512and spacers 548 a may provide the protective layers 549 a, 549 b. Theopen end of the protective bag 549 may be sealed together, or againstthe lightguide surfaces 528, 532, to form a hermetic enclosure aroundmedium gaps 544 a, 544 b. A protective sleeve may also be used in lieuof a protective bag to provide the protective layers 549 a, 549 b, withthe ends of the protective sleeve appropriately sealed to provide asealed enclosure for the medium gaps 544 a, 544 b.

Portions of protective layers 549 a, 549 b may squeeze into the spacesbetween respective spacers 548 a, 548 b as the protective layers 549 a,549 b deform at points of contact with spacers 548 a, 548 b. Thethickness of protective layers 549 a, 549 b may be selected to begreater than a diameter or width of the respective spacers 548 a, 548 bso that the protective layers 549 a, 549 b do not deform and fill thegaps between the spacers. As an example, the protective layers 549 a,549 b may have a thickness in a range from 50 microns to 100 microns,with the condition that the spacers 548 a, 548 b have a diameter orwidth less than the thickness of the respective protective layers.Preferably, the protective layers 548 a, 548 b have a refractive indexthat matches or substantially matches that of lens 504.

Lightguide 512 may have the same properties as described above forlightguide 112. Lightguide 512 may be planar, as shown in FIG. 8A, ormay be curved, i.e., not lying flat on a plane. An input coupler 552 maybe positioned on or proximate any of lightguide surfaces 528, 532 tocouple light into lightguide 512 as described previously for inputcoupler 152 and lightguide 112. An output coupler 556 may be positionedon or proximate any of lightguide surfaces 528, 532 to couple light outof lightguide 512 as previously described for output coupler 156 andlightguide 112. Lightguide 512 may be made of the same materials aspreviously described for lightguide 112. In general, lightguide 512 ismade of a material that is transparent to at least some electromagneticwavelengths, e.g., wavelengths in the visible range.

Spacers 548 a, 548 b may be microbeads, as shown in FIG. 8A, or may beother types of spacers, such as micropillars. Spacers 548 a, 548 b mayhave the same properties as described previously for spacers thatmaintain or set a medium gap, e.g., spacers 148. In order to enablelight to propagate along lightguide 512 by total internal reflection,medium gaps 544 a, 544 b may contain air or other medium having arefractive index that is lower than a refractive index of lightguide512. The heights of medium gaps 544 a, 544 b are generally set byrespective spacers 548 a, 548 b and may satisfy the same conditionspreviously described for medium gap 144. For example, the height of eachof medium gaps 544 a, 544 b, as set by the respective spacers, may be ina range from 2 to 100 microns, or in a range from 2 to 50 microns, or ina range from 2 microns to 10 microns, or in a range from 2 microns to 6microns, or in a range from 2 microns to 4 microns.

Lens 504 has lens surfaces 504 a, 504 b. These surfaces may be curvedsurfaces, e.g., lens surface 504 a may be a convex surface and lenssurface 504 b may be a concave surface, i.e., lens 504 may be a meniscuslens. Alternatively, lens 504 may be a planoconvex lens, where lenssurface 504 a is convex and lens surface 504 b is planar. In general,the curvature of the lens surfaces 504 a, 504 b may be selected based ona desired optical power of the optical combiner lens 500. Lens 504 maybe made of the same materials as previously described for lens 108. Ingeneral, lens 504 is preferably made of a material that is transparentto at least wavelengths in the visible range.

In another implementation, instead of providing spacers 548 a, 548 b onthe lightguide surfaces that are separate from respective protectivelayers 549 a, 549 b, the protective layers may be patterned to providethe respective spacers. FIG. 8C shows an example where surfaces ofprotective layers 549 a′, 549 b′ in contact with lightguide surfaces528, 532, respectively, are patterned to provide spacers 548 a′, 548 b′,respectively. Spacers 548 a′, 548 b′ will serve the same function asdescribed above for spacers 548 a, 548 b, i.e., define medium gapsbetween the lightguide surfaces 518, 532 and lens 504. Protective layers549 a′, 549 b′ can be made of a conformable or deformable material aspreviously described so as to conform to the shapes of lightguidesurfaces 528, 532, respectively.

FIG. 9 shows wearable heads-up display 404″ with optical combiner lens500 (from FIG. 8A) coupling light from display light source 428 to eye432. Optical combiner lens 500 may be carried by a support structure 400of wearable heads-up display 404″ (as shown for optical combiner lens100 and wearable heads-up display 404 in FIG. 7A). Any of the variationsof optical combiner lens 500 shown in FIGS. 8B and 8C may be used inwearable heads-up display 404″ of FIG. 9.

The above description of illustrated embodiments, including what isdescribed in the Abstract of the disclosure, is not intended to beexhaustive or to limit the embodiments to the precise forms disclosed.Although specific embodiments and examples are described herein forillustrative purposes, various equivalent modifications can be madewithout departing from the spirit and scope of the disclosure, as willbe recognized by those skilled in the relevant art. The teachingsprovided herein of the various embodiments can be applied to otherportable and/or wearable electronic devices, not necessarily theexemplary wearable electronic devices generally described above.

1. An optical combiner lens, comprising: a lens; and a lightguideassembly embedded in the lens, the lightguide assembly comprising: afirst protective layer; a second protective layer; a lightguide having afirst lightguide surface and a second lightguide surface, the lightguidedisposed between the first protective layer and the second protectivelayer; a plurality of first spacers arranged between the firstlightguide surface and the first protective layer; and a plurality ofsecond spacers arranged between the second lightguide surface and thesecond protective layer.
 2. The optical combiner lens of claim 2,wherein the lens is molded around the lightguide assembly.
 3. Theoptical combiner lens of claim 2, wherein a refractive index of each ofthe first protective layer and the second protective layer is selectedto match a refractive index of the lens.
 4. The optical combiner lens ofclaim 2, wherein the lens has a first lens surface that is convex and asecond lens surface that is concave or planar, and wherein thelightguide is arranged in a stack with the first lens surface and thesecond lens surface.
 5. The optical combiner lens of claim 2, whereinthe first protective layer and the second protective layer are each madeof a transparent polymer.
 6. The optical combiner lens of claim 2,wherein the lightguide assembly includes an input coupler carried by thelightguide in a position to couple light into the lightguide and anoutput coupler carried by the lightguide in a position to couple lightout of the lightguide.
 7. The optical combiner lens of claim 2, whereinthe first and second protective layers form a sealed enclosure aroundthe lightguide and spacers.
 8. The optical combiner lens of claim 2,wherein the first protective layer has a patterned surface that providesthe first spacers and/or the second protective layer has a patternedsurface that provides the second spacers.
 9. The optical combiner lensof claim 1, wherein the spacers are microbeads.
 10. The optical combinerlens of claim 1, wherein the first spacers set a first gap between thefirst lightguide surface and the lens, wherein the second spacers set asecond gap between the second lightguide surface and the lens, andwherein each of the first and second gaps has a height of at least 2microns.
 11. The optical combiner lens of claim 1, wherein the firstspacers set a first gap between the first lightguide surface and thelens, wherein the second spacers set a second gap between the secondlightguide surface and the lens, and wherein each of the first andsecond gaps has a height in a range from 2 microns to 100 microns.
 12. Awearable heads-up display comprising: a support structure; a displaylight source coupled to the support structure; and an optical combinerlens coupled to the support structure, the optical combiner lenscomprising: a lens; a protective enclosure embedded in the lens; alightguide contained in the protective enclosure; a plurality of firstspacers arranged between a first surface of the lightguide and theprotective enclosure, the first spacers providing a first gap betweenthe lightguide and the lens; and a plurality of second spacers arrangedbetween a second surface of lightguide and the protective enclosure, thesecond spacers providing a second gap between the lightguide and thelens.
 13. The wearable heads-up display of claim 12, wherein theprotective enclosure comprises a transparent polymer.
 14. The wearableheads-up display of claim 12, wherein a refractive index of theprotective enclosure is selected to match a refractive index of thelens.
 15. The wearable heads-up display of claim 12, wherein a patternedsurface of the protective enclosure provides the first spacers and/orthe second spacers.
 16. The wearable heads-up display of claim 12,wherein the spacers are microbeads.
 17. The wearable heads-up display ofclaim 12, wherein a height of each of the first and second gaps is in arange from 2 microns to 100 microns.
 18. The wearable heads-up displayof claim 12, wherein the lens has a first lens surface that is convexand a second lens surface that is concave or planar, and wherein thelightguide is intermediate between the first lens surface and the secondlens surface.
 19. The wearable heads-up display of claim 12, wherein theoptical combiner lens further comprises an output coupler carried by thelightguide and positioned to couple light out of the lightguide.
 20. Thewearable heads-up display of claim 19, wherein the optical combiner lensfurther comprises an input coupler carried by the lightguide andpositioned to couple light into the lightguide.